TWM609618U - Device for promoting wound healing by polymer low-temperature ion gas - Google Patents

Abstract

This creation is a high-molecular low-temperature ionized gas promoting wound healing device, which includes an oil-free air compressor, a first molecular sieve, and multiple layers of ionized air generators. The first molecular sieve is connected to an oil-free air compressor and can purify oxygen in the air. The ionized air generator is connected to the first molecular sieve; each ionized air generator includes an outer metal tube, an inner metal tube, a dielectric insulating ceramic sheet, and an air outlet tube. The dielectric insulating ceramic sheet is arranged between the outer metal tube and the inner metal tube, and forms an ion strike space with the outer metal tube. The air outlet pipe is connected to the ion strike space. The first molecular sieve and the ionized air generator can produce high-molecular and low-temperature ionic gas and nitrogen-containing heterocyclic compounds, which can produce the Bohr effect on the wound, quickly heal the wound and restore skin ductility.

Description

Device for promoting wound healing by polymer low-temperature ion gas

This creation relates to a medical auxiliary device, especially a high-molecular low-temperature ion gas to promote wound healing.

In the prior art, for the general wound treatment process of skin trauma, the wound is generally cleaned and disinfected first, then the wound is treated with gauze dressing and regular dressing changes, and finally medical supplies such as artificial skin are used to promote the wound. Heal and avoid leaving scars.

However, the existing processing method has the following disadvantages:

First, gauze dressing and regular dressing changes will take a long time for the wound to heal, and the wound will be exposed to the risk of a second infection during the dressing change process.

Second, in the process of dressing, the tissue fluid produced by the wound will stick to the gauze and will solidify and scab after a period of time. Therefore, it is necessary to tear the gauze off the wound before changing the dressing. In this way, it will not only cause pain and discomfort for the injured, but also destroy the original scab wound and regenerate the wound.

Third, although the existing treatment method can eventually heal the wound, the skin extensibility of the newly formed skin at the original wound site after healing will be greatly reduced (the normal skin extensibility is about 145%, but after the existing treatment method is healed The skin ductility of the wound is only 100%), which in turn leads to inconvenience for the injured.

In view of the aforementioned shortcomings and deficiencies of the prior art, the present invention provides a high-molecular low-temperature ion gas to promote wound healing device. Among them, macromolecules are defined as reactive gas molecules produced by the low-pressure reaction of atmospheric plasma. The high polymer low-temperature ionic gas promotes wound healing device can generate ionic gas and generate nitrogen-containing heterocyclic compound, and can make the ionic gas and nitrogen-containing heterocyclic compound contact with the wound through pressure blowing, and the Bohr effect occurs in the wound ( Bohr effect), so that the skin at the wound can produce a cortical membrane, which can quickly restore the healing wound and help to restore the skin ductility naturally.

In order to achieve the above creative goals, the technical means used in this creation is to design a high-molecular low-temperature ion gas to promote wound healing device, which includes: A power supply, which contains A high voltage terminal; A low-voltage terminal; An oil-free air compressor that can supply pressurized gas; A first molecular sieve connected to the oil-free air compressor; the first molecular sieve can screen molecules other than oxygen in the gas supplied by the oil-free air compressor; Multiple layers of ionized air generators are connected to the first molecular sieve; each ionized air generator includes An outer metal tube electrically connected to the low-voltage terminal of the power supply; An inner metal tube electrically connected to the high voltage terminal of the power supply; A dielectric insulating ceramic sheet, which is arranged between the outer metal tube and the inner metal tube, and an ion strike space is formed between the outer metal tube and the outer metal tube; An air outlet pipe communicates with the ion strike space; the gas supplied by the oil-free air compressor can flow to the first molecular sieve, the ion strike space, and the air outlet pipe in sequence.

The advantage of this creation is that the air is purified by the first molecular sieve chromatography (ie, molecules other than the oxygen in the air are sieved), so that the oxygen concentration in the air is about 90% to 93%. Since the purified air has sufficient oxygen concentration, after the purified air is passed into the ionized gas generator, it can produce polymers and at the same time produce low-temperature oxygen atoms, oxygen molecules, and ozone obtained by pressure purification and ionization. , Nitric oxide molecules, carbon dioxide. Moreover, further through the multi-channel application of ionized gas generators (that is, multiple layers of ionized gas generators are used in parallel), sufficient amounts of the aforementioned gases and ions can be generated; and when there are sufficient amounts of the aforementioned gases As well as ions, it can naturally react to form nitrogen-containing heterocyclic compounds after being collected in the outlet pipe. Thereby, the gases and ions including nitrogen-containing heterocyclic compounds can be blown onto the wound through the pressure of the oil-free air compressor, so that the nitrogen-containing heterocyclic compounds can contact the wound and further interact with the wounded. The water molecules react to produce the Bohr effect. In this way, the Bohr effect can make the skin produce cortical membranes, which can quickly restore healing wounds and help naturally restore skin ductility. When using this creation, you only need to blow air towards the wound, which can be used by the wounded on their own. It can not only be effectively sterilized by ozone, but also can quickly recover and heal the wound through the Bohr effect. It can be avoided without the need for dressing change There will be no sticking, tissue hyperplasia, or scab in the secondary infection, so it can effectively reduce the pain during treatment.

Furthermore, in the device for promoting wound healing with high polymer low-temperature ion gas, the first molecular sieve is a 5A molecular sieve.

Furthermore, the high-molecular low-temperature ion gas promotes wound healing device, wherein the high-molecular low-temperature ion gas promotes wound healing device further comprises a second molecular sieve, which is connected to the oil-free air compressor and the first molecular sieve It can filter out water molecules in the gas supplied by the oil-free air compressor; the gas supplied by the oil-free air compressor can flow to the first molecular sieve through the second molecular sieve.

Furthermore, in the device for promoting wound healing by polymer low-temperature ion gas, the second molecular sieve is 4A molecular sieve.

Further, the high-molecular low-temperature ionized gas promotes wound healing device, wherein the high-molecular low-temperature ionized gas promotes wound healing device further includes an air jet assembly, which includes a connecting tube connected to the plurality of layers of ionized air generation The outlet pipe of the device; the connecting pipe can be bent; a nozzle piece, which is arranged on the connecting pipe, and includes a nozzle connected to the connecting pipe; the gas supplied by the oil-free air compressor can pass through the plural The outlet pipe of the layered ionized air generator flows to the connecting pipe and is ejected through the nozzle.

Furthermore, in the device for promoting wound healing by polymer low-temperature ion gas, the air-jet assembly further includes a knob which is arranged on the nozzle piece and can adjust the caliber of the nozzle.

In the following, in conjunction with the drawings and preferred embodiments of this creation, the technical means adopted by this creation to achieve the predetermined creation purpose are further explained.

Please refer to Figure 1. The polymer low-temperature ionized gas promoting wound healing device of this invention includes a power supply 10, an oil-free air compressor 20, a first molecular sieve 30, a second molecular sieve 40, and a plurality of ionized air generators 50 , And a jet assembly 60. Moreover, in this embodiment, the aforementioned components are connected by a closed pipeline, which can ensure that they are not disturbed by the air in the environment.

The power supply 10 includes a high-voltage electric terminal 11 and a low-voltage electric terminal 12. In this embodiment, the power supply 10 has a power cord 13 for connecting to a power generating device, and transforms the high voltage terminal 11 to provide high voltage power and the low voltage terminal 12 to provide low voltage power. However, in other embodiments, the power supply 10 may also have a storage battery, so that it can be easily carried.

The oil-free air compressor 20 is a piston type air compressor in this embodiment, which is used to provide the gas pressure in the entire system as the jet power source of the final jet assembly 60. The oil-free air compressor 20 can supply gas with pressure; and the oil-free air compressor 20 can preliminarily dry the air before the first molecular sieve 30 to achieve a preliminary sterilization effect and facilitate subsequent use.

The first molecular sieve 30 is connected to the oil-free air compressor 20, and can screen molecules other than oxygen in the gas supplied by the oil-free air compressor 20, that is, the concentration of oxygen in the chromatographically purified air. Specifically, the first molecular sieve 30 may be a 5A molecular sieve. Generally, the oxygen concentration in the air is about 23%, and the oxygen concentration in the air purified by the first molecular sieve 30 can reach 90% to 93%.

The second molecular sieve 40 is connected between the oil-free air compressor 20 and the first molecular sieve 30, and can filter out water molecules in the gas supplied by the oil-free air compressor 20, that is, the gas can be dried. Specifically, the second molecular sieve 40 may be a 4A molecular sieve. The gas supplied by the oil-free air compressor 20 can flow through the second molecular sieve 40 to the first molecular sieve 30, whereby the second molecular sieve 40 can dry the air more completely before the air enters the first molecular sieve 30 to achieve a certain sterilization effect .

The plurality of layers of ionized air generators 50 are connected to the first molecular sieve 30; in other words, a plurality of ionized air generators 50 are arranged in parallel, and all the ionized air generators 50 are individually connected to the first molecular sieve 30 to achieve ionization The multi-channel application of the air generator 50 enables the first molecular sieve 30 to supply chromatographically purified air to all the ionized air generators 50 at the same time, so as to facilitate the generation of a sufficient amount of required gas. Each ionized air generator 50 includes an outer metal tube 51, an inner metal tube 52, a dielectric insulating ceramic sheet 53, and an air outlet tube 54. The outer metal tube 51 is electrically connected to the low-voltage terminal 12 of the power supply 10. The inner metal tube 52 is electrically connected to the high voltage terminal 11 of the power supply 10. The dielectric insulating ceramic sheet 53 is disposed between the outer metal tube 51 and the inner metal tube 52, and an ion striking space 55 is formed between the outer metal tube 51 and the outer metal tube 51 to ionize the air there. The air outlet pipe 54 is connected to the ion strike space 55, and the gas supplied by the oil-free air compressor 20 can flow to the first molecular sieve 30, the ion strike space 55, and the air outlet pipe 54 in sequence.

Specifically, when air with an oxygen concentration of 90% to 93% enters the ionized air generator 50, the oxygen concentration in the ion strike space 55 is 90% to 93% at a voltage of 5KW/V to 8KW/V. The corona discharge is carried out in the air, which uses the negative electrons in the voltage to dissociate the oxygen molecules in the air into multiple oxygen atoms. These oxygen atoms will automatically bond to the same under normal temperature and pressure. The oxygen molecules and ozone of the plain body, therefore, after the aforementioned ionization process, oxygen atoms, oxygen molecules, ozone, nitric oxide molecules, and carbon dioxide can be generated, and through the multi-channel application of the ionized air generator 50, Then enough oxygen atoms, oxygen molecules, ozone, nitric oxide molecules, and carbon dioxide can be obtained.

Please further refer to FIG. 2, the air jet assembly 60 includes a connecting pipe 61, a nozzle 62, and a knob 63. The connecting pipe 61 is connected to the air outlet pipe 54 of the multiple-layer ionized air generator 50, that is, the air outlet pipe 54 of the multiple-layer ionized air generator 50 is collected and connected to the connecting pipe 61. The connecting tube 61 can be bent, and specifically, the connecting tube 61 may be a rubber hose or a metal hose. The nozzle 62 is arranged on the connecting pipe 61 and includes a nozzle; the nozzle is connected to the connecting pipe 61, and the gas supplied by the oil-free air compressor 20 can flow to the outlet pipe 54 of the plurality of layers of ionized air generators 50 The pipe 61 is connected and ejected through the nozzle. In this way, the user can move the nozzle member 62 arbitrarily by virtue of the bendability of the connecting tube 61, and hold the nozzle member 62 to blow air towards the wound, so as to apply to any part of the wound. The knob 63 is arranged on the nozzle piece 62 and can adjust the size of the nozzle. Specifically, the way in which the knob 63 adjusts the size of the nozzle orifice can be a structure that adjusts the water flow rate of a faucet. Since the entire system is connected by a closed pipeline, when the nozzle of the nozzle member 62 is opened, the pressure provided by the oil-free air compressor 20 can be used as a power to eject the ionized gas, and the diameter of the nozzle will affect it. The speed of the gas jet, so the knob 63 is used to adjust the speed and intensity of the jet at the end. In addition, the speed and intensity of the gas ejected from the nozzle can be controlled to a better range by the knob 63 according to the situation, which means that the appropriate ejection speed and intensity can be used in the corresponding situation, which can be more advantageous. For wound healing and recovery of skin ductility.

When sufficient oxygen atoms, oxygen molecules, ozone, nitric oxide molecules, and carbon dioxide are collected (at the junction of the outlet pipe 54 and the connecting pipe 61), they can naturally react to form nitrogen-containing heterocyclic compounds; The gas in the assembly 60 contains the aforementioned gases, ions, and nitrogen-containing heterocyclic compounds. Therefore, when the nozzle is opened, the pressure of the oil-free air compressor 20 can remove the aforementioned gases, ions, and The nitrogen heterocyclic compound is sprayed out to facilitate the user to stroke the wound.

In addition, the present invention further includes an air storage tank 71 and a plurality of radiating fins 72 in this embodiment. The air storage tank 71 is connected between the first molecular sieve 30 and the ionized air generator 50 connected in parallel, and the radiating fins 72 are provided in the air. The outer surface of the storage tank 71 can thereby temporarily store the gas passing through the first molecular sieve 30 and dissipate heat and reduce the temperature. The air storage tank 71 and the heat sink 72 may be replaced by a heat dissipation coil in other embodiments, or the air storage tank 71 and the heat sink 72 may not be provided in other embodiments.

Furthermore, in order to reduce the number of bacteria in the above-mentioned gas, a silver nanofiber (not shown in the figure) can also be installed in front of the first molecular sieve 30 to preliminarily filter and sterilize the air.

When used in this creation, the air is first compressed by an oil-free air compressor 20, then sent to the second molecular sieve 40 for drying, and then chromatographically purified by the first molecular sieve 30 to make the oxygen concentration reach 90% to 93%, and then high The oxygen-concentrated air is simultaneously fed into the parallel ionized air generator 50, so that the high-oxygen-concentrated air is ionized in the ion strike space 55 to generate oxygen atoms, oxygen molecules, ozone, nitric oxide molecules, and carbon dioxide. Then, when all the air processed by the ionized air generator 50 is collected, it can react in the air-jet assembly 60 to generate nitrogen heterocyclic compounds. Finally, the user can open the nozzle of the air-jet assembly 60 and adjust it with the knob 63 Proper jet speed and intensity to blow the treated gas to the wound.

The advantage of this invention is that the first molecular sieve 30 is used to chromatographically purify the air, so that the oxygen concentration in the air is about 90% to 93%. Since the purified air has sufficient oxygen concentration, after the purified air is passed into the ionized gas generator, polymers can be produced and at the same time low-temperature oxygen atoms, oxygen molecules, and ozone obtained by pressure purification and ionization can be produced. , Nitric oxide molecules, carbon dioxide. Moreover, further through the multi-channel application of ionized gas generators (ie, multiple layers of ionized gas generators are used in parallel), sufficient amounts of the aforementioned gases and ions can be generated; and when sufficient amounts of the aforementioned gases are present When it is combined with ions, it can naturally react to form a nitrogen-containing heterocyclic compound after being collected in the outlet pipe 54. Thereby, the gases and ions including the nitrogen-containing heterocyclic compound can be blown onto the wound through the pressure of the oil-free air compressor 20, so that the nitrogen-containing heterocyclic compound contacts the wound and further interacts with the wounded. The Bohr effect occurs in response to the water. In this way, the Bohr effect can make the skin produce cortical membranes, which can quickly restore healing wounds and help naturally restore skin ductility. This creation only needs to blow air towards the wound, which is convenient for the wounded to use on their own. It can not only be effectively sterilized by ozone, but also can quickly heal the wound through the Bohr effect. It does not require a dressing change process to avoid secondary infections. , There will be no sticking, tissue hyperplasia, or crusting, so it can effectively reduce the pain during treatment.

The above description is only the preferred embodiment of the creation, and does not limit the creation in any form. Although the creation has been disclosed in the preferred embodiment as above, it is not intended to limit the creation. Any technical field has Generally knowledgeable persons, without departing from the scope of this creative technical solution, can use the technical content disclosed above to make slight changes or modifications to equivalent embodiments with equivalent changes. However, any content that does not deviate from this creative technical solution is based on this Any simple modifications, equivalent changes and modifications made to the above embodiments by the technical essence of the creation still fall within the scope of the technical solution for creation.

10: Power supply 11: High voltage terminal 12: Low voltage terminal 13: Power cord 20: Oil-free air compressor 30: The first molecular sieve 40: second molecular sieve 50: Ionized air generator 51: Outer metal tube 52: inner metal pipe 53: Dielectric insulating ceramic sheet 54: Exhaust pipe 55: Ion Strike Space 60: Jet assembly 61: connecting pipe 62: nozzle piece 63: Knob 71: air storage tank 72: heat sink

Figure 1 is a schematic diagram of the pipeline configuration of this author. Figure 2 is a partial enlarged schematic diagram of the air-jet assembly of this creation.

10: Power supply

11: High voltage terminal

12: Low voltage terminal

13: Power cord

20: Oil-free air compressor

30: The first molecular sieve

40: second molecular sieve

50: Ionized air generator

51: Outer metal tube

52: inner metal pipe

53: Dielectric insulating ceramic sheet

54: Exhaust pipe

55: Ion Strike Space

60: Jet assembly

71: air storage tank

72: heat sink

Claims (6)

A high-molecular low-temperature ion gas promotes wound healing device, which contains A power supply, which contains A high voltage terminal; A low-voltage terminal; An oil-free air compressor that can supply pressurized gas; A first molecular sieve connected to the oil-free air compressor; the first molecular sieve can screen molecules other than oxygen in the gas supplied by the oil-free air compressor; Multiple layers of ionized air generators are connected to the first molecular sieve; each ionized air generator includes An outer metal tube electrically connected to the low-voltage terminal of the power supply; An inner metal tube electrically connected to the high voltage terminal of the power supply; A dielectric insulating ceramic sheet, which is arranged between the outer metal tube and the inner metal tube, and an ion strike space is formed between the outer metal tube and the outer metal tube; An air outlet pipe communicates with the ion strike space; the gas supplied by the oil-free air compressor can flow to the first molecular sieve, the ion strike space, and the air outlet pipe in sequence. The device for promoting wound healing with polymer low-temperature ion gas according to claim 1, wherein the first molecular sieve is a 5A molecular sieve. The high-molecular low-temperature ion gas promoting wound healing device according to claim 1 or 2, wherein the high-molecular low-temperature ion gas promoting wound healing device further comprises A second molecular sieve, which is connected between the oil-free air compressor and the first molecular sieve, and can filter out water molecules in the gas supplied by the oil-free air compressor; Gas can flow to the first molecular sieve through the second molecular sieve. The device for promoting wound healing with polymer low-temperature ion gas according to claim 3, wherein the second molecular sieve is 4A molecular sieve. The high-molecular low-temperature ion gas promoting wound healing device according to claim 1 or 2, wherein the high-molecular low-temperature ion gas promoting wound healing device further comprises An air jet assembly, which contains A connecting pipe connected to the air outlet pipe of the plurality of layers of ionized air generators; the connecting pipe can be bent; A nozzle piece, which is arranged on the connecting pipe and includes A nozzle is connected to the connecting pipe; the gas supplied by the oil-free air compressor can flow to the connecting pipe through the outlet pipe of the plurality of layers of ionized air generators, and be ejected through the nozzle. The high-molecular low-temperature ion gas promoted wound healing device according to claim 5, wherein the air-jet assembly further comprises A knob is arranged on the nozzle piece and can adjust the caliber of the nozzle.

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